Development of Relatively Simple Sample Pretreatment Strategies to Selectively Remove Chromatographic Interfering Peaks of Polysorbate 80 from Liquid Oral Finished Drug Product.

Polysorbate 80 (PS 80) is a nonionic surfactant, used in myriad of pharmaceutical, food and cosmetic formulations. PS 80 components have strong UV absorbance and retain under reversed-phase chromatographic conditions, significantly masking sections of the chromatogram. PS 80-related peaks interferences in a sample are common and can be difficult to separate from the analyte peaks. A liquid oral finished product (LOFP) containing PS 80 and Ivermectin as the active pharmaceutical ingredient (API) was selected for this study. Herein, we report two sample pretreatment strategies focusing on the selective removal of PS 80 from the LOFP. Both methods significantly reduce and/or practically eliminate excipients and PS 80-related peaks interferences from the LOFP without a negative impact on the API and its key-related substances recovery. The solid-phase extraction (SPE) strategy uses a C18 SPE followed by a silica gel SPE, whereas the liquid-liquid extraction strategy uses in situ-generated sodium caprylate for the removal of formulation excipients and PS 80. These methods can significantly increase the reliability of high-performance liquid chromatography methods and decrease false positive out-of-specifications events because of coelution of PS 80-related peaks with peaks of interest.

Improved Stability-Indicating RP-UPLC Method for the Levamisole Hydrochloride Assay and Estimation of Its Related Compounds.

BACKGROUND: Levamisole hydrochloride (LVM) is an anthelmintic drug substance with immunomodulatory and anticancer activities. LVM has also found usage as a cutting agent in street cocaine. OBJECTIVE: This study was aimed to develop and validate an alternative and improved stability-indicating reversed-phase ultraperformance liquid chromatography (RP-UPLC) method for the determination of LVM and the estimation of its related compounds. METHOD: The UPLC method for the assay was optimized in terms of organic solvents consumed, pH, column temperature, and flow rate. Determination of LVM and its related compounds was performed using a gradient elution on a Waters ACQUITY UPLC® BEH C18 (50 mm × 2.1 mm i.d., 130 Å). The column temperature was maintained at 35°C. Mobile phase A was composed of aqueous 5 mM ammonium hydroxide, and mobile phase B was composed of acetonitrile. All the analytes were monitored by UV detection at 215 nm with a flow rate of 0.7 mL/min. The total runtime of the method with column equilibration is 4.0 min. RESULTS: The developed method met all the acceptance criteria of the current International Council for Harmonization [ICH Q2 (R1)] guidelines. The method was tested in terms of specificity, linearity (R2 > 0.999), limit of detection (LOD; 0.06 µg/mL), limit of quantitation (LOQ; 0.2 µg/mL), accuracy, precision, and robustness. With a short analysis time (<2.5 min) and reduced consumption of organic solvents, the proposed method is considered a greener alternative to conventional chromatographic methods. CONCLUSIONS: An alternative and improved UPLC method was successfully developed and validated in accordance with the ICH guidelines for the determination of LVM and the estimation of its related compounds. HIGHLIGHTS: Due to its high degree of selectivity, speed, and accuracy, the developed method can significantly benefit the end-users with laboratory efficiency and throughput during routine analysis of production batches and stability monitoring of LVM-related drug products.

Development of a Simple Extraction Procedure and an HPLC Method for the Determination of Delmopinol in a Challenging Rubbery Dental Chew.

BACKGROUND: Delmopinol hydrochloride (delmopinol) is widely used in oral hygiene products such as dental chews for preventing dental plaque buildup and gingivitis. OBJECTIVE: This study aimed to develop a simple and inexpensive extraction method, followed by a stability-indicating reversed-phase HPLC (RP-HPLC) method for the determination of delmopinol from rubbery dental chews. METHODS: The extraction method was optimized in terms of pH, temperature, solvents, repeatability, and reproducibility. Delmopinol was extracted from the rubbery dental chews using 6 N NaOH-MeOH (1 + 1, v/v) at 65°C. The delmopinol peak was eluted in about 7 min by gradient elution on a pH-stable (alkaline) Phenomenex Gemini-NX-C18 column (50 × 4.6 mm id, 110 Å, 3 µm particle size) maintained at 50°C. Mobile phase A was composed of aqueous 10 mM ammonium hydroxide and mobile phase B was acetonitrile. The analyte was monitored by UV detection at 220 nm with a flow rate of 2.0 mL/min. RESULTS: The method was successfully validated as per the current International Conference on Harmonization guidelines for delmopinol with respect to specificity, linearity (R2 >0.999), accuracy, precision, LOQ (2 µg/mL), LOD (0.6 µg/mL), and robustness. The reliability of the method was also demonstrated by batch analysis of 132 dental chews. CONCLUSION: A simple extraction method and RP-HPLC method were successfully developed and validated for the determination of delmopinol from rubbery dental chews. HIGHLIGHTS: The overall method was demonstrated to be accurate, robust, specific, and stability-indicating. Therefore, the developed method is suitable and highly desirable for routine analysis of delmopinol in its finished drug products.

Comprehensive study on degradation profile of firocoxib and structural elucidation of its key degradation products.

Firocoxib is widely used in veterinary medicine as a non-steroidal analgesic and anti-inflammatory drug substance. Herein, a comprehensive study on the degradation profile of firocoxib was performed through force degradation studies to understand its degradation profile and characterize its major degradation products (DPs). Firocoxib drug substance was subjected to acidic, alkaline, oxidation (H2O2, KMnO4, and K2Cr2O7), thermal (solid and solution state), and photolytic (solid and solution state) stress degradation, as recommended in the ICH guidelines. Firocoxib and its major DPs were adequately separated by investigational HPLC method, which utilized a HALO C18 (100 × 2.1 mm, 2.0 µm) column. Mobile phase-A for the HPLC method is composed of 0.1% formic acid in water and mobile phase-B acetonitrile. A total of six major DPs were observed for firocoxib drug substance under these stress degradation conditions. Structural elucidation of the DPs performed using liquid chromatography-high resolution mass spectrometry and comparison of their fragmentation profile with that of the parent compound. For further structural confirmation of two major DPs, DP-2 and DP-6 were isolated and purified from the stressed samples using a preparative HPLC and analyzed by comprehensive nuclear magnetic resonance (NMR) spectroscopy studies. Most probable mechanistic pathways for the formation of DPs of firocoxib under various stress degradation conditions were postulated to understand its degradation profile. Based on the results from forced degradation, firocoxib was found to be quite stable under basic and thermal conditions, and somewhat unstable under acidic, oxidative, and photolytic conditions. The results of this study should facilitate quality monitoring and establish a stability profile of firocoxib drug substance and drug products. These results may also assist in the design and development of new formulations made with firocoxib drug substance with desired shelf life.

Structural elucidation of major degradation products of milbemycin oxime drug substance using LC-MS and NMR.

Milbemycin oxime (MO) drug substance is a 16-membered macrocyclic lactone that exhibits a broad spectrum of biological activity and high potency towards parasites. In this study, a comprehensive forced degradation study was carried out on MO drug substance to identify and characterize its major degradation products (DPs). MO drug substance was subjected to acid, base, oxidation (H2O2), heat (solid and solution state), and photolytic (solid and solution state) stress degradation as per the ICH guidelines. Chromatographic separation of the drug substance (MO A3 and MO A4) and its DPs was achieved using a gradient elution on a HALO C18 column (100 × 4.6 mm, 2.7 µm). Mobile phase A consisted of water/acetonitrile (60/40, v/v) and mobile phase B consisted of ethanol/isopropanol (50/50, v/v). A total of twelve major DPs were observed for MO drug substance under various stress conditions. These DPs were further identified and characterized using liquid chromatography-high resolution mass spectrometry and comparison of their fragmentation profile with MO A4 and MO A3 using tandem mass spectrometry. Of these, H2O2 induced oxidative degradation product (3,4-dihydroperoxide MO A4) was isolated using semi-preparative HPLC and characterized by comparison of its nuclear magnetic resonance spectroscopy data with MO A4. The proposed structures of the DPs have been rationalized by appropriate degradation pathways for MO A4 and MO A3.

Identification and characterization of major degradation products of Eprinomectin drug substance including degradation pathways using LC-HRMS and NMR.

Eprinomectin (EPM) is a semi-synthetic potent antiparasitic drug widely used in veterinary medicine. In this study, a comprehensive forced degradation study was carried out on EPM drug substance as per ICH guidelines. Generation of adequate quantities of major degradation products of EPM via forced degradation studies was necessary for identification, structure elucidation, and understanding its degradation mechanism and degradation pathways. EPM drug substance was subjected to acid, base, oxidation (H2O2 and K2Cr2O7), thermal (solid and solution state), and photolytic (solid and solution state) stress degradation. The degradation products (DPs) formed in the stressed degraded samples were successfully separated using a gradient elution on a HALO C18 column (100 × 4.6 mm, 2.7 µm). Mobile phase A consisted of water and mobile phase B consisted of ethanol/isopropanol (98/2, v/v). A total of six major DPs of EPM drug substance formed under various stress conditions. The chemical structures of DPs were determined using liquid chromatography-high resolution mass spectrometry (LC-HRMS) and characterized through comparison of their fragmentation profile with EPM B1a using tandem mass spectrometry (MS/MS). Additionally, two solvates (methanol adduct B1a #1 and methanol adduct B1a #2) were observed during the acid-stressed degradation study of EPM in presence of methanol. To confirm the chemical structure, these products were isolated with semi-preparative HPLC and characterized by using a combination of LC-MS/MS and nuclear magnetic resonance spectroscopy. The elucidated chemical structure of the degradation products of EPM was also justified through mechanistic explanations. Identification and characterization of the DPs including degradation mechanism(s) of EPM should facilitate the understanding of the stability behavior of EPM drug substances as well as aid in the design of new formulations made with EPM.

A comprehensive study to identify and characterize major degradation products of Ivermectin drug substance including its degradation pathways using LC-HRMS and NMR.

Ivermectin (IVM) drug substance is a semi-synthetic macrocyclic lactone that exhibits a broad spectrum of activity and high potency towards endo- and ectoparasites. In this study, a comprehensive forced degradation study was carried out on IVM drug substance (under the conditions recommended in the ICH guidelines) to identify and characterize its major degradation products (DPs). IVM drug substance was subjected to acidic, alkaline, oxidation (H2O2 and K2Cr2O7), thermal (solid and solution state), and photolytic (solid and solution state) stress degradations. Chromatographic separation of the drug substance and its DPs was achieved using a gradient elution on a HALO C18 column (150 × 4.6 mm, 2.7 µm). A total of five major DPs were observed for IVM drug substance under various stressed conditions. Additionally, ivermectin API lots exhibited instability when stored under room temperature and at 45% relative humidity for two years. These DPs were identified and characterized using liquid chromatography-high resolution mass spectrometry (LC-HRMS) and a comparison of their fragmentation profile with IVM H2B1a using tandem mass spectrometry. Of these, H2O2 induced oxidative degradation product (3,4-epoxide H2B1a) was isolated using semi-preparative HPLC and its structure was elucidated comprehensively using LC-HRMS and nuclear magnetic resonance spectroscopy. The proposed structures of the DPs have been rationalized by appropriate degradation pathways of IVM H2B1a. Comprehensive degradation profile of IVM drug substance should facilitate the understanding of the stability profile of IVM drug substance, setting the specification of DPs in finished products as well as aid in the design of generic formulation made with IVM.

Simultaneous determination of ivermectin, clorsulon and their related substances in an injectable finished product by a stability-indicating RP-HPLC method.

A reversed-phase high performance liquid chromatography (RP-HPLC) method has been developed for the determination of ivermectin and clorsulon, including the identification and estimation of their related impurities in an ivermectin and clorsulon injectable finished product. Chromatographic separation was achieved using a gradient elution on a Supelco Ascentis® Express C18 column (150 mm × 4.6 mm i.d., 5 µm particle size) maintained at 55 °C. Mobile phase-A is composed of water and mobile phase-B is composed of acetonitrile/methanol (65/35, v/v). Analytes were monitored by UV detection at 245 nm. The stability-indicating capability of this method has been demonstrated by the adequate separation of all the process related impurities and degradation products of ivermectin and clorsulon from the stress degraded samples of the injectable product. This method was also successfully validated as per the current ICH guidelines with respect to specificity, linearity (R2> 0.999), limit of detection (0.3 µg/mL), limit of quantitation (1.0 µg/mL), accuracy, precision, and robustness for both APIs. This proposed method can significantly benefit the end-users in QC laboratories with laboratory efficiency and throughput during routine analysis and stability monitoring of the injectable product.

Assay of afoxolaner and determination of its related substances in commercial bulk batches of afoxolaner by reversed-phase HPLC method based on a short octadecyl column.

Afoxolaner is a new insecticidal and acaricidal active pharmaceutical ingredient (API) belonging to the isoxazoline family, widely prescribed for the control of fleas and ticks in dogs. A stability-indicating reversed-phase high performance liquid chromatography (RP-HPLC) method has been developed for the assay of afoxolaner and determination of its related compounds in bulk API lots of afoxolaner. The chromatographic separation of afoxolaner and its related compounds was achieved by gradient elution on a Zorbax-SB C18 column (50 mm × 4.6 mm i.d., 5 µm particle size) maintained at 40 °C. Mobile phase-A is composed of water and mobile phase-B is composed of acetonitrile/methanol (50/50, v/v). Analytes were monitored by UV detection at 225 nm with a flow rate of 2.0 mL/min. The stability-indicating capability of the method has been demonstrated by adequate separation of all the process related impurities and degradation products of afoxolaner generated by stress degradation of afoxolaner bulk drug substance under various stress conditions. This method was also successfully validated as per the current ICH guidelines for afoxolaner and Q6S07 (afoxolaner related substance) with respect to specificity, linearity (R2 > 0.999), detection limit (∼0.21 µg/mL), quantitation limit (∼0.70 µg/mL), accuracy, precision, and robustness. Due to its speed, high degree of selectivity, and accuracy, the proposed method is suitable and highly desirable in quality control laboratories for routine analysis of afoxolaner.

Two-step reaction mechanism reveals new antioxidant capability of cysteine disulfides against hydroxyl radical attack.

Cysteine disulfides, which constitute an important component in biological redox buffer systems, are highly reactive toward the hydroxyl radical (•OH). The mechanistic details of this reaction, however, remain unclear, largely due to the difficulty in characterizing unstable reaction products. Herein, we have developed a combined approach involving mass spectrometry (MS) and theoretical calculations to investigate reactions of •OH with cysteine disulfides (Cys-S-S-R) in the gas phase. Four types of first-generation products were identified: protonated ions of the cysteine thiyl radical (+Cys-S•), cysteine (+Cys-SH), cysteine sulfinyl radical (+Cys-SO•), and cysteine sulfenic acid (+Cys-SOH). The relative reaction rates and product branching ratios responded sensitively to the electronic property of the R group, providing key evidence to deriving a two-step reaction mechanism. The first step involved •OH conducting a back-side attack on one of the sulfur atoms, forming sulfenic acid (-SOH) and thiyl radical (-S•) product pairs. A subsequent H transfer step within the product complex was favored for protonated systems, generating sulfinyl radical (-SO•) and thiol (-SH) products. Because sulfenic acid is a potent scavenger of peroxyl radicals, our results implied that cysteine disulfide can form two lines of defense against reactive oxygen species, one using the cysteine disulfide itself and the other using the sulfenic acid product of the conversion of cysteine disulfide. This aspect suggested that, in a nonpolar environment, cysteine disulfides might play a more active role in the antioxidant network than previously appreciated.

Top-Down Analysis of Disulfide-Linked Proteins Using Photoinduced Radical Reactions and ET-DDC.

Top-down characterization of proteins via tandem mass spectrometry (MS/MS) can be challenging due to the presence of multiple disulfide bond linkages; which significantly inhibit the backbone cleavage efficiency for the formation of structurally informative fragment ions. In this study, we present a strategy of pairing a solution-phase photoinitiating system with dipolar direct current induced collisional activation of electron transfer products (ET-DDC) of proteins for a top-down MS/MS approach. The photoinitiating system allows for a rapid scission of all the disulfide linkages in the protein (on the time scale of seconds) with high efficiency (near to complete reduction); while ET-DDC collisional activation improves the fragmentation efficiency for the protein via broadband activation of all the first-generation charge reduced precursor ions (e.g., electron transfer no-dissociation or ETnoD products) from electron transfer reactions over a wide mass-to-charge range. As a result, this approach enabled the generation of extensive sequence informative fragment ion yields for a rapid and enhanced structural characterization of disulfide-linked proteins.

Dipolar DC induced collisional activation of non-dissociated electron-transfer products.

The application of electron transfer and dipolar direct current induced collisional activation (ET-DDC) for enhanced sequence coverage of peptide/protein cations is described. A DDC potential is applied across one pair of opposing rods in the high-pressure collision cell of a hybrid quadrupole/time-of-flight tandem mass spectrometer (QqTOF) to induce collisional activation, in conjunction with electron transfer reactions. As a broadband technique, DDC can be employed for the simultaneous collisional activation of all the first-generation charge-reduced precursor ions (eg, electron transfer no-dissociation or ETnoD products) from electron transfer reactions over a relatively broad mass-to-charge range. A systematic study of ET-DDC induced collision activation on peptide/protein cations revealed an increase in the variety (and abundances) of sequence informative fragment ions, mainly c- and z-type fragment ions, relative to products derived directly via electron transfer dissociation (ETD). Compared with ETD, which has low dissociation efficiency for low-charge-state precursor ions, ET-DDC also showed marked improvement, providing a sequence coverage of 80% to 85% for all the charge states of ubiquitin. Overall, this method provides a simple means for the broadband collisional activation of ETnoD ions in the same collision cell in which they are generated for improved structural characterization of polypeptide and protein cations subjected to ETD.

Acetone/Isopropanol Photoinitiating System Enables Tunable Disulfide Reduction and Disulfide Mapping via Tandem Mass Spectrometry.

Herein, we report the development of a new photochemical system which enables rapid and tunable disulfide bond reduction and its application in disulfide mapping via online coupling with mass spectrometry (MS). Acetone, a clean and electrospray ionization (ESI) compatible solvent, is used as the photoinitiator (1% volume) in the solvent system consisting of 1:1 alkyl alcohol and water. Under ultraviolet (UV) irradiation (∼254 nm), the acetone/alcohol system produces hydroxyalkyl radicals, which are responsible for disulfide bond cleavage in peptides. Acetone/isopropanol is most suitable for optimizing the disulfide reduction products, leading to almost complete conversion in less than 5 s when the reaction is conducted in a flow microreactor. The flow microreactor device not only facilitates direct coupling with ESI-MS but also allows fine-tuning of the extent of disulfide reduction by varying the UV exposure time. Near full sequence coverage for peptides consisting of intra- or interchain disulfide bonds has been achieved from complete disulfide reduction and online tandem mass spectrometry (MS/MS) via low energy collision-induced dissociation. Coupling different degrees of partial disulfide reduction with ESI-MS/MS allows disulfide mapping as demonstrated for characterizing the three disulfide bonds in insulin.

Heptamolybdate: a highly active sulfide oxygenation catalyst.

The sulfide oxygenation activities of both heptamolybdate ([Mo7O24]6-, [1]6-) and its peroxo adduct [Mo7O22(O2)2]6- ([2]6-) were examined in this contribution. [Mo7O22(O2)2]6- was prepared in a yield of 65% from (NH4)6[Mo7O24] (1a) upon treatment of 10 equiv. of H2O2 and structurally identified through single crystal X-ray diffraction study. (nBu4N)6[Mo7O22(O2)2] (2b) is an efficient catalyst for the sequential oxygenation of methyl phenyl sulfide (MPS) by H2O2 to the corresponding sulfoxide and subsequently sulfone with a 100% utility of H2O2. Surprisingly, (nBu4N)6[Mo7O24] (1b) is a significantly faster catalyst than 2b for MPS oxygenation under identical conditions. The pseudo-first order kcat constants from initial rate kinetics are 54 M-1 s-1 and 19 M-1 s-1 for 1b and 2b, respectively. Electrospray ionization mass spectrometry (ESI-MS) investigation of 1b under the catalytic reaction conditions revealed that [Mo2O11]2- is likely the main active species in sulfide oxygenation by H2O2.

Shotgun Analysis of Diacylglycerols Enabled by Thiol-ene Click Chemistry.

Diacylglycerols (DAGs) are a subclass of neutral lipids actively involved in cell signaling and metabolism. Alteration in DAG metabolism has been associated with onset and progression of several human-related diseases. The structural diversity of DAGs and their low concentrations in biological samples call for the development of methods that are capable of sensitive identification and quantitation of each DAG species as well as rapid profiling when a biochemical pathway is perturbed. In this work, the thiol-ene click chemistry has been employed to introduce a charge-tag, namely, cysteamine (CA), at a carbon-carbon double bond (C═C) of unsaturated DAGs. This one-pot photochemical derivatization is fast (within 1 min), universal (monotagging) for DAGs varying in fatty acyl chain lengths and the number of C═Cs, and suitable for small sample volume (e.g., 1-50 µL plasma). Because of the presence of the amine group in CA, tagged DAGs showed at least 10 times increase in response to electrospray ionization as compared to conventional ammonium adduct formation. Low-energy collision-induced dissociation of CA tagged DAGs allowed confident assignment of fatty acyl composition. A neutral loss scan based on characteristic 95 Da loss (a combined loss of CA and H2O) of tagged DAGs has been established as a sensitive means for unsaturated DAG detection (limit of detection = 100 pM) and quantitation from mixtures. The analytical utility of CA tagging was demonstrated by shotgun analysis of unsaturated DAGs in human plasma, including samples from type 2 diabetes mellitus patients.

Expedient syntheses of N-heterocycles via intermolecular amphoteric diamination of allenes.

Saturated 1,4-diazo heterocycles including piperazines, 1,4-diazepanes, and 1,4-diazocanes, are highly important for therapeutic development, but their syntheses are often tedious. We describe here an amphoteric diamination strategy to unite readily available 1,2-, 1,3- or 1,4-diamine derivatives with electron-deficient allenes via a formal [n + 2] (n = 4, 5, 6) cyclization mode to produce the corresponding 1,4-diazo heterocycles in just one step. This strategy features mild reaction conditions, high functional group tolerance, and scalability (gram scale). The reagents used are cheap and readily available and no transition metal catalysts are needed. More sophisticated products containing trifluoromethyl group or bicyclic ring systems can be accessed via a one-pot procedure as well. Our mechanistic studies support that formation of mono-iodinated or chlorinated diamine intermediates is important for the desired transformation and the commonly proposed chloride-iodide exchange process and a radical N-C bond formation is unlikely when the combination of NCS/KI is used.

Reactivity of hydropersulfides toward the hydroxyl radical unraveled: disulfide bond cleavage, hydrogen atom transfer, and proton-coupled electron transfer.

Hydropersulfides (RSSH) are highly reactive as nucleophiles and hydrogen atom transfer reagents. These chemical properties are believed to be key for them to act as antioxidants in cells. The reaction involving the radical species and the disulfide bond (S-S) in RSSH, a known redox-active group, however, has been scarcely studied, resulting in an incomplete understanding of the chemical nature of RSSH. We have performed a high-level theoretical investigation on the reactions of the hydroxyl radical (˙OH) toward a set of RSSH (R = -H, -CH3, -NH2, -C(O)OH, -CN, and -NO2). The results show that S-S cleavage and H-atom abstraction are the two competing channels. The electron inductive effect of R induces selective ˙OH substitution at one sulfur atom upon S-S cleavage, forming RSOH and ˙SH for the electron donating groups (EDGs), whereas producing HSOH and ˙SR for the electron withdrawing groups (EWGs). The H-Atom abstraction by ˙OH follows a classical hydrogen atom transfer (hat) mechanism, producing RSS˙ and H2O. Surprisingly, a proton-coupled electron transfer (pcet) process also occurs for R being an EDG. Although for RSSH having EWGs hat is the leading channel, S-S cleavage can be competitive or even dominant for the EDGs. The overall reactivity of RSSH toward ˙OH attack is greatly enhanced with the presence of an EDG, with CH3SSH being the most reactive species found in this study (overall rate constant: 4.55 × 1012 M-1 s-1). Our results highlight the complexity in RSSH reaction chemistry, the extent of which is closely modulated by the inductive effect of the substituents in the case of the oxidation by hydroxyl radicals.

Thiyl Radical-Based Charge Tagging Enables Sterol Quantitation via Mass Spectrometry.

Inspired by the high reactivity and specificity of thiyl radicals toward alkenes, we have developed a new charge derivatization method to enable fast and quantitative analysis of sterols via electrospray ionization-mass spectrometry (ESI-MS). Thioglycolic acid (TGA), a commercially available compound, has been established as a highly efficient tagging reagent. Initiated from photochemical reactions, the thiyl radical derived from TGA abstracts an allylic hydrogen in the B ring of sterols, forming a radical intermediate which rapidly recombines with a second thiyl radical to produce the final tagged product. Because of the incorporation of a carboxylic acid group, TGA tagging not only improves the limit of detection (sub-nM) for sterols but also facilitates their quantitation via characteristic 44 Da neutral loss scan. This radical based derivatization is fast (1 min) and efficient (>90% yield) when conducted in a flow microreactor. The analytical utility of thiyl radical charge tagging method has been demonstrated by quantifying sterols from human plasma and vegetable oil.

Stereospecific Suzuki, Sonogashira, and Negishi coupling reactions of N-alkoxyimidoyl iodides and bromides.

A high-yielding stereospecific route to the synthesis of single geometric isomers of diaryl oxime ethers through Suzuki coupling of N-alkoxyimidoyl iodides is described. This reaction occurs with complete retention of the imidoyl halide geometry to give single E- or Z-isomers of diaryl oxime ethers. The Sonogashira coupling of N-alkoxyimidoyl iodides and bromides with a wide variety of terminal alkynes to afford single geometric isomers of aryl alkynyl oxime ethers has also been developed. Several of these reactions proceed through copper-free conditions. The Negishi coupling of N-alkoxyimidoyl halides is introduced. The E and Z configurations of nine Suzuki-coupling products and two Sonogashira-coupling products were confirmed by X-ray crystallography.